The first decisions to make about InnoDB
configuration involve the configuration of data files, log files,
page size, and memory buffers, which should be configured before
initializing InnoDB
. Modifying the
configuration after InnoDB
is initialized may
involve non-trivial procedures.
This section provides information about specifying
InnoDB
settings in a configuration file,
viewing InnoDB
initialization information, and
important storage considerations.
Because MySQL uses data file, log file, and page size settings
to initialize InnoDB
, it is recommended that
you define these settings in an option file that MySQL reads at
startup, prior to initializing InnoDB
.
Normally, InnoDB
is initialized when the
MySQL server is started for the first time.
You can place InnoDB
options in the
[mysqld]
group of any option file that your
server reads when it starts. The locations of MySQL option files
are described in Section 6.2.2.2, “Using Option Files”.
To make sure that mysqld reads options only
from a specific file (and mysqld-auto.cnf
),
use the --defaults-file
option
as the first option on the command line when starting the
server:
mysqld --defaults-file=path_to_option_file
To view InnoDB
initialization information
during startup, start mysqld from a command
prompt, which prints initialization information to the console.
For example, on Windows, if mysqld is located
in C:\Program Files\MySQL\MySQL Server
9.1\bin
, start the MySQL server like
this:
C:\> "C:\Program Files\MySQL\MySQL Server 9.1\bin\mysqld" --console
On Unix-like systems, mysqld is located in
the bin
directory of your MySQL
installation:
$> bin/mysqld --user=mysql &
If you do not send server output to the console, check the error
log after startup to see the initialization information
InnoDB
printed during the startup process.
For information about starting MySQL using other methods, see Section 2.9.5, “Starting and Stopping MySQL Automatically”.
InnoDB
does not open all user tables and
associated data files at startup. However,
InnoDB
does check for the existence of
tablespace files referenced in the data dictionary. If a
tablespace file is not found, InnoDB
logs
an error and continues the startup sequence. Tablespace files
referenced in the redo log may be opened during crash recovery
for redo application.
Review the following storage-related considerations before proceeding with your startup configuration.
In some cases, you can improve database performance by placing data and log files on separate physical disks. You can also use raw disk partitions (raw devices) for
InnoDB
data files, which may speed up I/O. See Using Raw Disk Partitions for the System Tablespace.InnoDB
is a transaction-safe (ACID compliant) storage engine with commit, rollback, and crash-recovery capabilities to protect user data. However, it cannot do so if the underlying operating system or hardware does not work as advertised. Many operating systems or disk subsystems may delay or reorder write operations to improve performance. On some operating systems, the veryfsync()
system call that should wait until all unwritten data for a file has been flushed might actually return before the data has been flushed to stable storage. Because of this, an operating system crash or a power outage may destroy recently committed data, or in the worst case, even corrupt the database because write operations have been reordered. If data integrity is important to you, perform “pull-the-plug” tests before using anything in production. On macOS,InnoDB
uses a specialfcntl()
file flush method. Under Linux, it is advisable to disable the write-back cache.On ATA/SATA disk drives, a command such
hdparm -W0 /dev/hda
may work to disable the write-back cache. Beware that some drives or disk controllers may be unable to disable the write-back cache.With regard to
InnoDB
recovery capabilities that protect user data,InnoDB
uses a file flush technique involving a structure called the doublewrite buffer, which is enabled by default (innodb_doublewrite=ON
). The doublewrite buffer adds safety to recovery following an unexpected exit or power outage, and improves performance on most varieties of Unix by reducing the need forfsync()
operations. It is recommended that theinnodb_doublewrite
option remains enabled if you are concerned with data integrity or possible failures. For information about the doublewrite buffer, see Section 17.11.1, “InnoDB Disk I/O”.Before using NFS with
InnoDB
, review potential issues outlined in Using NFS with MySQL.
The innodb_data_file_path
option defines the name, size, and attributes of
InnoDB
system tablespace data files. If you
do not configure this option prior to initializing the MySQL
server, the default behavior is to create a single
auto-extending data file, slightly larger than 12MB, named
ibdata1
:
mysql> SHOW VARIABLES LIKE 'innodb_data_file_path';
+-----------------------+------------------------+
| Variable_name | Value |
+-----------------------+------------------------+
| innodb_data_file_path | ibdata1:12M:autoextend |
+-----------------------+------------------------+
The full data file specification syntax includes the file name,
file size, autoextend
attribute, and
max
attribute:
file_name:file_size[:autoextend[:max:max_file_size]]
File sizes are specified in kilobytes, megabytes, or gigabytes
by appending K
, M
or
G
to the size value. If specifying the data
file size in kilobytes, do so in multiples of 1024. Otherwise,
kilobyte values are rounded to nearest megabyte (MB) boundary.
The sum of file sizes must be, at a minimum, slightly larger
than 12MB.
You can specify more than one data file using a semicolon-separated list. For example:
[mysqld]
innodb_data_file_path=ibdata1:50M;ibdata2:50M:autoextend
The autoextend
and max
attributes can be used only for the data file that is specified
last.
When the autoextend
attribute is specified,
the data file automatically increases in size by 64MB increments
as space is required. The
innodb_autoextend_increment
variable controls the increment size.
To specify a maximum size for an auto-extending data file, use
the max
attribute following the
autoextend
attribute. Use the
max
attribute only in cases where
constraining disk usage is of critical importance. The following
configuration permits ibdata1
to grow to a
limit of 500MB:
[mysqld]
innodb_data_file_path=ibdata1:12M:autoextend:max:500M
A minimum file size is enforced for the
first system tablespace data file to ensure
that there is enough space for doublewrite buffer pages. The
following table shows minimum file sizes for each
InnoDB
page size. The default
InnoDB
page size is 16384 (16KB).
Page Size (innodb_page_size) | Minimum File Size |
---|---|
16384 (16KB) or less | 3MB |
32768 (32KB) | 6MB |
65536 (64KB) | 12MB |
If your disk becomes full, you can add a data file on another disk. For instructions, see Resizing the System Tablespace.
The size limit for individual files is determined by your operating system. You can set the file size to more than 4GB on operating systems that support large files. You can also use raw disk partitions as data files. See Using Raw Disk Partitions for the System Tablespace.
InnoDB
is not aware of the file system
maximum file size, so be cautious on file systems where the
maximum file size is a small value such as 2GB.
System tablespace files are created in the data directory by
default (datadir
). To specify
an alternate location, use the
innodb_data_home_dir
option.
For example, to create a system tablespace data file in a
directory named myibdata
, use this
configuration:
[mysqld]
innodb_data_home_dir = /myibdata/
innodb_data_file_path=ibdata1:50M:autoextend
A trailing slash is required when specifying a value for
innodb_data_home_dir
.
InnoDB
does not create directories, so ensure
that the specified directory exists before you start the server.
Also, ensure sure that the MySQL server has the proper access
rights to create files in the directory.
InnoDB
forms the directory path for each data
file by textually concatenating the value of
innodb_data_home_dir
to the
data file name. If
innodb_data_home_dir
is not
defined, the default value is “./”, which is the
data directory. (The MySQL server changes its current working
directory to the data directory when it begins executing.)
Alternatively, you can specify an absolute path for system tablespace data files. The following configuration is equivalent to the preceding one:
[mysqld]
innodb_data_file_path=/myibdata/ibdata1:50M:autoextend
When you specify an absolute path for
innodb_data_file_path
, the
setting is not concatenated with the
innodb_data_home_dir
setting.
System tablespace files are created in the specified absolute
path. The specified directory must exist before you start the
server.
The InnoDB
doublewrite buffer storage area
resides in doublewrite files, which provides flexibility with
respect to the storage location of doublewrite pages. In
previous releases, the doublewrite buffer storage area resided
in the system tablespace. The
innodb_doublewrite_dir
variable
defines the directory where InnoDB
creates
doublewrite files at startup. If no directory is specified,
doublewrite files are created in the
innodb_data_home_dir
directory,
which defaults to the data directory if unspecified.
To have doublewrite files created in a location other than the
innodb_data_home_dir
directory,
configure
innodb_doublewrite_dir
variable. For example:
innodb_doublewrite_dir=/path/to/doublewrite_directory
Other doublewrite buffer variables permit defining the number of doublewrite files, the number of pages per thread, and the doublewrite batch size. For more information about doublewrite buffer configuration, see Section 17.6.4, “Doublewrite Buffer”.
The amount of disk space occupied by redo log files is
controlled by the
innodb_redo_log_capacity
variable, which can be set at startup or runtime; for example,
to set the variable to 8GiB in an option file, add the following
entry:
[mysqld]
innodb_redo_log_capacity = 8589934592
For information about configuring redo log capacity at runtime, see Configuring Redo Log Capacity.
The innodb_redo_log_capacity
variable supersedes the
innodb_log_file_size
and
innodb_log_files_in_group
variables, which are deprecated. When the
innodb_redo_log_capacity
setting is defined,
the innodb_log_file_size
and
innodb_log_files_in_group
settings are
ignored; otherwise, if one or both of these deprecated settings
are defined then they are used to compute
Innodb_redo_log_capacity_resized
as (innodb_log_files_in_group
*
innodb_log_file_size
). If none of those
variables are set, then the default
innodb_redo_log_capacity
value is used.
InnoDB
attempts to maintain 32 redo log
files, with each file equal to 1/32 *
innodb_redo_log_capacity
. The redo log files
reside in the #innodb_redo
directory in the
data directory unless a different directory was specified by the
innodb_log_group_home_dir
variable. If innodb_log_group_home_dir
was
defined, the redo log files reside in the
#innodb_redo
directory in that directory.
For more information, see Section 17.6.5, “Redo Log”.
You can define a different number of redo log files and
different redo log file size when initializing the MySQL Server
instance by configuring the
innodb_log_files_in_group
and
innodb_log_file_size
variables.
innodb_log_files_in_group
defines the number of log files in the log group. The default
and recommended value is 2.
innodb_log_file_size
defines
the size in bytes of each log file in the log group. The
combined log file size
(innodb_log_file_size
*
innodb_log_files_in_group
)
cannot exceed the maximum value, which is slightly less than
512GB. A pair of 255 GB log files, for example, approaches the
limit but does not exceed it. The default log file size is 48MB.
Generally, the combined size of the log files should be large
enough that the server can smooth out peaks and troughs in
workload activity, which often means that there is enough redo
log space to handle more than an hour of write activity. A
larger log file size means less checkpoint flush activity in the
buffer pool, which reduces disk I/O. For additional information,
see Section 10.5.4, “Optimizing InnoDB Redo Logging”.
The innodb_log_group_home_dir
defines the directory path to the InnoDB
log
files. You might use this option to place
InnoDB
redo log files in a different physical
storage location than InnoDB
data files to
avoid potential I/O resource conflicts; for example:
[mysqld]
innodb_log_group_home_dir = /dr3/iblogs
InnoDB
does not create directories, so make
sure that the log directory exists before you start the
server. Use the Unix or DOS mkdir
command
to create any necessary directories.
Make sure that the MySQL server has the proper access rights to create files in the log directory. More generally, the server must have access rights in any directory where it needs to create files.
Undo logs, by default, reside in two undo tablespaces created when the MySQL instance is initialized.
The innodb_undo_directory
variable defines the path where InnoDB
creates default undo tablespaces. If that variable is undefined,
default undo tablespaces are created in the data directory. The
innodb_undo_directory
variable
is not dynamic. Configuring it requires restarting the server.
The I/O patterns for undo logs make undo tablespaces good candidates for SSD storage.
For information about configuring additional undo tablespaces, see Section 17.6.3.4, “Undo Tablespaces”.
The global temporary tablespace stores rollback segments for changes made to user-created temporary tables.
A single auto-extending global temporary tablespace data file
named ibtmp1
in the
innodb_data_home_dir
directory
by default. The initial file size is slightly larger than 12MB.
The innodb_temp_data_file_path
option specifies the path, file name, and file size for global
temporary tablespace data files. File size is specified in KB,
MB, or GB by appending K, M, or G to the size value. The file
size or combined file size must be slightly larger than 12MB.
To specify an alternate location for global temporary tablespace
data files, configure the
innodb_temp_data_file_path
option at startup.
In MySQL 9.1, InnoDB
is always
used as the on-disk storage engine for internal temporary
tables.
The innodb_temp_tablespaces_dir
variable defines the location where InnoDB
creates session temporary tablespaces. The default location is
the #innodb_temp
directory in the data
directory.
To specify an alternate location for session temporary
tablespaces, configure the
innodb_temp_tablespaces_dir
variable at startup. A fully qualified path or path relative to
the data directory is permitted.
The innodb_page_size
option
specifies the page size for all InnoDB
tablespaces in a MySQL instance. This value is set when the
instance is created and remains constant afterward. Valid values
are 64KB, 32KB, 16KB (the default), 8KB, and 4KB. Alternatively,
you can specify page size in bytes (65536, 32768, 16384, 8192,
4096).
The default 16KB page size is appropriate for a wide range of
workloads, particularly for queries involving table scans and
DML operations involving bulk updates. Smaller page sizes might
be more efficient for OLTP workloads involving many small
writes, where contention can be an issue when a single page
contains many rows. Smaller pages can also be more efficient for
SSD storage devices, which typically use small block sizes.
Keeping the InnoDB
page size close to the
storage device block size minimizes the amount of unchanged data
that is rewritten to disk.
innodb_page_size
can be set
only when initializing the data directory. See the description
of this variable for more information.
MySQL allocates memory to various caches and buffers to improve
performance of database operations. When allocating memory for
InnoDB
, always consider memory required by
the operating system, memory allocated to other applications,
and memory allocated for other MySQL buffers and caches. For
example, if you use MyISAM
tables, consider
the amount of memory allocated for the key buffer
(key_buffer_size
). For an
overview of MySQL buffers and caches, see
Section 10.12.3.1, “How MySQL Uses Memory”.
Buffers specific to InnoDB
are configured
using the following parameters:
innodb_buffer_pool_size
defines size of the buffer pool, which is the memory area that holds cached data forInnoDB
tables, indexes, and other auxiliary buffers. The size of the buffer pool is important for system performance, and it is typically recommended thatinnodb_buffer_pool_size
is configured to 50 to 75 percent of system memory. The default buffer pool size is 128MB. For additional guidance, see Section 10.12.3.1, “How MySQL Uses Memory”. For information about how to configureInnoDB
buffer pool size, see Section 17.8.3.1, “Configuring InnoDB Buffer Pool Size”. Buffer pool size can be configured at startup or dynamically.On systems with a large amount of memory, you can improve concurrency by dividing the buffer pool into multiple buffer pool instances. The number of buffer pool instances is controlled by the by
innodb_buffer_pool_instances
option. By default,InnoDB
creates one buffer pool instance. The number of buffer pool instances can be configured at startup. For more information, see Section 17.8.3.2, “Configuring Multiple Buffer Pool Instances”.innodb_log_buffer_size
defines the size of the buffer thatInnoDB
uses to write to the log files on disk. The default size is 64MB. A large log buffer enables large transactions to run without writing the log to disk before the transactions commit. If you have transactions that update, insert, or delete many rows, you might consider increasing the size of the log buffer to save disk I/O.innodb_log_buffer_size
can be configured at startup. For related information, see Section 10.5.4, “Optimizing InnoDB Redo Logging”.
On 32-bit GNU/Linux x86, if memory usage is set too high,
glibc
may permit the process heap to grow
over the thread stacks, causing a server failure. It is a risk
if the memory allocated to the mysqld
process for global and per-thread buffers and caches is close
to or exceeds 2GB.
A formula similar to the following that calculates global and per-thread memory allocation for MySQL can be used to estimate MySQL memory usage. You may need to modify the formula to account for buffers and caches in your MySQL version and configuration. For an overview of MySQL buffers and caches, see Section 10.12.3.1, “How MySQL Uses Memory”.
innodb_buffer_pool_size
+ key_buffer_size
+ max_connections*(sort_buffer_size+read_buffer_size+binlog_cache_size)
+ max_connections*2MB
Each thread uses a stack (often 2MB, but only 256KB in MySQL
binaries provided by Oracle Corporation.) and in the worst
case also uses sort_buffer_size +
read_buffer_size
additional memory.
On Linux, if the kernel is enabled for large page support,
InnoDB
can use large pages to allocate memory
for its buffer pool. See Section 10.12.3.3, “Enabling Large Page Support”.